CN213008452U - Multifunctional walking mechanism - Google Patents

Abstract

The utility model relates to the technical field of robots, a multifunctional travelling mechanism is disclosed, which is arranged on a vehicle frame, the vehicle frame is provided with a first direction and a second direction which are mutually perpendicular, the multifunctional travelling mechanism comprises a first travelling device, a second travelling device, a first driving device and a second driving device, the first travelling device and the second travelling device are arranged at intervals along the first direction, the first travelling device and the second travelling device both comprise a first travelling wheel and a second travelling wheel, and the first travelling wheel and the second travelling wheel are coaxially arranged along the second direction; the first driving device is used for driving a first travelling wheel of the first travelling device and a second travelling wheel of the second travelling device to synchronously rotate, and the second driving device is used for driving a second travelling wheel of the first travelling device and a first travelling wheel of the second travelling device to synchronously rotate. The utility model discloses a multi-functional running gear can reach and hinder the ability reinforce more, the stationarity is good and the fast purpose of walking.

Description

Multifunctional walking mechanism

Technical Field

The utility model relates to the technical field of robot, especially, relate to a multi-functional running gear.

Background

At present, robot moving platforms at home and abroad can be divided into a wheeled robot and a tracked robot according to a walking mechanism, the wheeled robot comprises at least two wheeled mechanisms, each wheeled mechanism is a walking wheel, the wheeled robot has the advantages of high efficiency, high speed and stable action, but the obstacle crossing capability of the wheeled robot is limited, and the wheeled robot cannot pass through a road edge and a stair step; the walking mechanism of the crawler-type robot is a crawler, the crawler-type robot has the advantages of high efficiency, strong obstacle-crossing capability and stable action, but the walking speed of the crawler-type robot is slow and heavy; therefore, the walking mechanism of the existing robot cannot have the advantages of high walking speed and strong obstacle crossing capability at the same time.

SUMMERY OF THE UTILITY MODEL

The utility model aims at: the utility model provides a multifunctional walking mechanism to reach the purpose that obstacle crossing ability is strong, the stationarity is good and walking speed is fast.

In order to achieve the above object, the present invention provides a multifunctional traveling mechanism, which is disposed on a frame, the frame has a first direction and a second direction perpendicular to each other, and the multifunctional traveling mechanism includes a first traveling device, a second traveling device, a first driving device and a second driving device, the first traveling device and the second traveling device are disposed at intervals along the first direction, the first traveling device and the second traveling device both include a first traveling wheel and a second traveling wheel, and the first traveling wheel and the second traveling wheel are disposed coaxially along the second direction;

the first driving device is used for driving a first travelling wheel of the first travelling device and a second travelling wheel of the second travelling device to synchronously rotate, and the second driving device is used for driving a second travelling wheel of the first travelling device and a first travelling wheel of the second travelling device to synchronously rotate;

a control mechanism electrically connected to the first drive device and the second drive device.

In some embodiments of the present application, each of the first traveling wheel and the second traveling wheel includes a hub and a support portion, the hub of the first traveling wheel is connected to a power output end of the first driving device or a power output end of the second driving device through a first transmission assembly, and the hub of the second traveling wheel is connected to a power output end of the first driving device or a power output end of the second driving device through a second transmission assembly;

the wheel hub has a supporting leg extending in a direction away from the center thereof, and the supporting portion is provided at one end of the supporting leg away from the center of the wheel hub.

In some embodiments of the present application, the hub has at least two of the support legs, and the same is true of the hub all of the support legs are uniformly arranged along the circumference of the hub.

In some embodiments of the present application, an included angle between any two adjacent support legs of the same first walking device or the same second walking device is equal.

In some embodiments of the present application, the support legs of the same first walking device or the same second walking device are disposed close to each other in a pair manner.

In some embodiments of the present application, the hub has three of the support legs, and three of the support legs are Y-shaped.

In some embodiments of the present application, the supporting portion is a supporting pad or a roller.

In some embodiments of the present application, each of the first driving device and the second driving device includes an electric motor and a first transmission shaft, the electric motor is disposed on the frame, and the first transmission shaft is connected to a motor shaft of the electric motor;

the first transmission assembly comprises a first transmission main wheel, a first transmission driven wheel and a first transmission belt, and the second transmission assembly comprises a second transmission main wheel, a second transmission driven wheel and a second transmission belt;

the first transmission main wheel and the second transmission main wheel are rotationally connected with the first transmission shaft, the first transmission driven wheel is connected with the hub of the first walking wheel through a rotating device, and the first transmission main wheel and the first transmission driven wheel are connected through the first transmission belt;

the second transmission driven wheel is connected with a hub of the second road wheel, and the second transmission main wheel and the second transmission driven wheel are connected through the second transmission belt.

In some embodiments of the present application, the rotating device includes a second transmission shaft, a first bearing and a second bearing, one end of the second transmission shaft is connected to the frame through the first bearing, the first transmission wheel is in transmission connection with the second transmission shaft, and a hub of the first traveling wheel is rotatably connected to the other end of the second transmission shaft;

the second transmission shaft penetrates through the inner ring of the second bearing, the outer ring of the second bearing is embedded in the inner hole of the second travelling wheel, and the diameter of the inner hole of the second transmission driven wheel is larger than the outer diameter of the second transmission shaft.

In some embodiments of the present application, the first road wheels and the second road wheels are staggered.

The embodiment of the utility model provides a multifunctional walking mechanism, it compares with prior art, and its beneficial effect lies in:

each traveling wheel of each traveling device is driven by the corresponding driving device, so that the traveling mechanism has stronger power and wider application range and can pass through complex terrains such as road edges, stairs and the like; in addition, the first driving device is used for driving the first travelling wheel of the first travelling device and the second travelling wheel of the second travelling device to synchronously rotate, the second driving device is used for driving the second travelling wheel of the first travelling device and the first travelling wheel of the second travelling device to synchronously rotate, and compared with the condition that each travelling wheel is driven to rotate by a single driving device, the number of the driving devices of the travelling mechanism is less, so that the design requirement of the multifunctional travelling mechanism on the driving device is reduced, and the multifunctional travelling mechanism has the advantages of simple structure and controllable cost; in addition, because the walking wheels are of a wheel type structure, compared with a crawler type structure, the wheel type structure has the advantages of light weight, high walking speed and small jolt, and therefore the multifunctional walking mechanism also has the advantages of higher flexibility and better stability.

Drawings

Fig. 1 is a first schematic structural diagram of the mobile platform of the multifunctional robot according to the embodiment of the present invention in a fast translation state.

Fig. 2 is a schematic structural diagram ii of the multifunctional robot mobile platform according to the embodiment of the present invention in a fast translation state.

Fig. 3 is a side view of the mobile platform of the multifunctional robot according to the embodiment of the present invention.

Fig. 4 is a sectional view of fig. 3.

Fig. 5 is a schematic view of the structure of fig. 4 at a.

Fig. 6 is a schematic view of the structure of fig. 4 at B.

Fig. 7 is a schematic structural diagram of the multifunctional robot mobile platform according to the embodiment of the present invention, when the multifunctional robot mobile platform is dynamically adjusted forward.

Fig. 8 is a schematic structural diagram of the multifunctional robot mobile platform according to the embodiment of the present invention, which is in a backward dynamic adjustment state.

Fig. 9 is a schematic structural diagram of the robot moving platform according to the embodiment of the present invention in an obstacle crossing state.

Fig. 10 is a schematic view of a connection structure of the first driving device, the second driving device, the first transmission assembly and the second transmission assembly according to the embodiment of the present invention.

In the figure, 1, a frame; 2. a traveling mechanism; 21a, a first walking device; 211a, a first travelling wheel; 2111a, a hub; 2112a, support legs; 2113a, a support portion; 212a, a second road wheel; 2121a, a hub; 2122a, a support leg; 2123a, a support portion; 21b, a second running gear; 211b, a first running wheel; 2111b, a hub; 2112b, support legs; 2113b, a support portion; 212b, a second road wheel; 2121b, a hub; 2122b, legs; 2123b, a support portion; 22a, a first driving device; 221a, a motor; 222a, a first transmission shaft; 22b, a second driving device; 221b, a motor; 222b, a first transmission shaft; 3. a first transmission assembly; 31. A first drive main wheel; 32. a first drive from the wheel; 33. a first drive belt; 4. a second transmission assembly; 41. a second drive main wheel; 42. the second transmission is driven by the wheel; 43. a second belt; 5. a rotating device; 51. a second drive shaft; 52. a first bearing; 53. a second bearing; 6. a power source.

Detailed Description

The following detailed description of the embodiments of the present invention is provided with reference to the accompanying drawings and examples. The following examples are intended to illustrate the invention, but are not intended to limit the scope of the invention.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "left", "right", "top", "bottom", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present invention.

As shown in fig. 1-10, the utility model provides a multifunctional robot mobile platform, it includes: the device comprises a frame 1, a traveling mechanism 2 and a control mechanism; the frame 1 has a first direction and a second direction which are perpendicular to each other; the travelling mechanisms 2 are arranged on the frame 1 and are at least two, each travelling mechanism 2 comprises a first travelling device 21a, a second travelling device 21b, a first driving device 22a and a second driving device 22b, the first travelling devices 21a and the second travelling devices 21b are arranged at intervals along a first direction, each travelling device 21a and each travelling device 21b comprises a first travelling wheel and a second travelling wheel, and the first travelling wheels and the second travelling wheels are coaxially arranged along a second direction; the first driving device 22a is used for driving the first travelling wheel of the first travelling device 21a and the second travelling wheel of the second travelling device 21b to synchronously rotate, and the second driving device 22b is used for driving the second travelling wheel of the first travelling device 21a and the first travelling wheel of the second travelling device 21b to synchronously rotate; and a control mechanism electrically connected to the first drive device 22a and the second drive device 22 b.

Based on the arrangement, each travelling wheel of each travelling device is driven by the corresponding driving device, so that the travelling mechanism 2 has stronger power and wider application range and can pass through complex terrains such as road edges, stairs and the like; in addition, the first driving device 22a is used for driving the first traveling wheel of the first traveling device 21a and the second traveling wheel of the second traveling device 21b to synchronously rotate, and the second driving device 22b is used for driving the second traveling wheel of the first traveling device 21a and the first traveling wheel of the second traveling device 21b to synchronously rotate, compared with the case that each traveling wheel is driven to rotate by a single driving device, the number of driving devices of the traveling mechanism 2 is less, therefore, the design requirement of the robot moving platform on the driving devices is reduced, and the robot moving platform has the advantages of simple structure and controllable cost; in addition, because the walking wheel is wheeled structure again, compare in crawler-type structure, wheeled structure has light in weight, walking speed is fast, the little advantage of jolting, consequently, this multifunctional robot moving platform still has the advantage that the flexibility ratio is higher, the stationarity is better.

Alternatively, in some embodiments, as shown in fig. 1-9, each of the first road wheel and the second road wheel includes a hub and a support portion, the hub of the first road wheel is connected to the power output end of the first driving device 22a or the power output end of the second driving device 22b through the first transmission assembly 3, and the hub of the second road wheel is connected to the power output end of the first driving device 22a or the power output end of the second driving device 22b through the second transmission assembly 4; the wheel hub has a supporting leg extending in a direction away from the center thereof, and the supporting portion is provided at one end of the supporting leg away from the center of the wheel hub. Based on the above-described structure, for convenience of explanation, the first traveling device 21a includes the first traveling wheel 211a and the second traveling wheel 211a, the first traveling wheel 211a includes the hub 2111a, the support leg 2112a, and the support portion 2113a, and the second traveling wheel 212a includes the hub 2121a, the support leg 2122a, and the support portion 2123 a; the second traveling device 21b includes a first traveling wheel 211b and a second traveling wheel 211b, the first traveling wheel 211b includes a hub 2111b, a support leg 2112b, and a support portion 2113b, the second traveling wheel 212b includes a hub 2121b, a support leg 2122b, and a support portion 2123b, the hub described below includes a hub 2111a, a hub 2121a, a hub 2111b, and a hub 2121b, the support leg includes a support leg 2112a, a support leg 2122a, a support leg 2112b, and a support portion 2122b, the support portion includes a support portion 2113a, a support portion 2123a, a support portion 2113b, and a support portion 2123 b;

the support part and the support legs provide stable support force for the multifunctional mobile platform; in addition, each driving device of the same walking mechanism 2 drives two walking wheels corresponding to the driving device to rotate, so that the supporting part of the same walking mechanism 2 is in contact with the ground alternately, and the multifunctional robot moving platform can move conveniently.

Alternatively, in some embodiments of the present application, as shown in fig. 1-9, the hub has at least two support legs, and all of the support legs of the same hub are uniformly arranged along the circumference of the hub. Therefore, the angle of each supporting leg which swings in unit time is the same, and the walking wheels have a more stable walking state.

Optionally, in some embodiments of the present application, as shown in fig. 1 to 2, the included angle between any two adjacent support legs of the same first walking device 21a or the same second walking device 21b is equal. Based on this, when the rotating speed output by the first driving device 22a is equal to the rotating speed output by the second driving device 22b, the rotating speed of the first traveling wheel is equal to the rotating speed of the second traveling wheel, and the supporting part of the first traveling wheel and the supporting part of the second traveling wheel are alternately contacted with the ground, so that the rapid translation of the multifunctional robot moving platform is realized.

Alternatively, in some embodiments of the present application, as shown in fig. 9, the support legs of the same first walking device 21a or second walking device 21b are arranged close to each other in a pair. Based on this, compared with the case that only one driving device drives one walking device to move, the first walking device 21a and the second walking device 21b of the embodiment of the present application contact with the ground through two support parts which are closely arranged in a pair in pairs, and the first walking wheel and the second walking wheel which drive each walking device are respectively provided by the corresponding first driving device 22a and the second driving device 22b, so as to increase the ground capturing force of the walking mechanism 2, and further improve the obstacle crossing capability of the robot moving platform; in addition, when the multifunctional robot moving platform is in an obstacle crossing state, the rotating speed output by the first driving device 22a is equal to the rotating speed output by the second driving device 22b, so that the stability of the multifunctional robot moving platform is better;

in addition, when the multifunctional robot moving platform is in an obstacle crossing state, the included angle between the axes of the two supporting legs which are arranged in a pair mode in pairs is 10-30 degrees.

Alternatively, in some embodiments of the present application, as shown in fig. 7 to 8, the multi-function robot mobile platform has a dynamic adjustment state, and for the same walking device, the walking wheel in contact with the ground is defined as a supporting wheel, the other walking wheel is defined as a swinging wheel, and one of the supporting portions of the supporting wheel is grounded; when the multifunctional robot moving platform moves forwards slowly, the first driving device 22a and the second driving device 22b rotate alternately, one of the traveling wheels of the first traveling device 21a and one of the traveling wheels of the second traveling device 21b rotate simultaneously, the swinging wheel swings clockwise towards the supporting wheel, an included angle between a grounded supporting part and a supporting part in front of the grounded supporting part is reduced until one of the supporting parts of the swinging wheel lands, the swinging wheel becomes a new supporting wheel at the moment, the original supporting wheel rotates clockwise, the original supporting wheel becomes a new swinging wheel, and the alternating process of the supporting wheel and the swinging wheel is circulated, so that the multifunctional robot moving platform can move forwards slowly;

when the multifunctional robot moving platform slowly moves backwards, the first driving device 22a and the second driving device 22b alternately rotate, one of the traveling wheels of the first traveling device 21a and one of the traveling wheels of the second traveling device 21b simultaneously rotate, the swinging wheel swings anticlockwise towards the supporting wheel, an included angle between a grounded supporting part and a supporting part behind the grounded supporting part is reduced until one of the supporting parts of the swinging wheel lands, the swinging wheel becomes a new supporting wheel at the moment, then the original supporting wheel rotates anticlockwise, the original supporting wheel becomes a new swinging wheel, and the alternating process of the supporting wheel and the swinging wheel is circulated, so that the multifunctional robot moving platform can slowly move backwards.

Optionally, in some embodiments of the present application, as shown in fig. 1 to 9, in order to enable the road wheel to be in better contact with the ground, the hub has three support legs, and the three support legs are arranged in a Y shape; of course, in other embodiments, the hub may have two support legs or four support legs, and the number of the support legs is not limited in the embodiments of the present application.

Optionally, in some embodiments of the present application, as shown in fig. 1 to 9, in order to further enable the traveling wheel to better contact with the ground, the supporting portion is a supporting pad or a roller, preferably, the supporting portion is a supporting pad, the supporting pad is made of rubber, and the service life of the rubber is longer.

Alternatively, in some embodiments of the present application, as shown in fig. 3, 4, 5, 6 and 9, each of the first driving device 22a and the second driving device 22b includes an electric motor and a first transmission shaft, the electric motor is disposed on the frame 1, and the first transmission shaft is connected to a motor shaft of the electric motor;

the first transmission assembly 3 comprises a first transmission main wheel 31, a first transmission driven wheel 32 and a first transmission belt 33, and the second transmission assembly 4 comprises a second transmission main wheel 41, a second transmission driven wheel 42 and a second transmission belt 43;

the first transmission main wheel 31 and the second transmission main wheel 41 are sequentially connected with a first transmission shaft in a rotating mode from inside to outside, the first transmission main wheel 31 and the first transmission driven wheel 32 are connected through a first transmission belt 33, the first transmission driven wheel 32 is connected with a hub of the first travelling wheel through a rotating device 5, the rotating device 5 comprises a second transmission shaft 51, a first bearing 52 and a second bearing 53, one end of the second transmission shaft 51 is connected with the frame 1 through the first bearing 52, the first transmission driven wheel 32 is connected with the second transmission shaft 51 in a rotating mode, and the first travelling wheel is connected with the other end of the second transmission shaft 51 in a rotating mode;

the second transmission shaft 51 penetrates through the inner ring of the second bearing 53, and the outer ring of the second bearing 53 is embedded in the inner hole of the second travelling wheel;

the second transmission driven wheel 42 is connected with a hub of the second road wheel, and the second transmission main wheel 41 and the second transmission driven wheel 42 are connected through a second transmission belt 43.

Based on the above structure, for convenience of description, the first driving device 22a includes the motor 221a and the first transmission shaft 222a, the second driving device 22b includes the motor 221b and the second transmission shaft 222b, the motors are hereinafter referred to as the motor 221a and the motor 221b, and the first transmission shaft is referred to as the first transmission shaft 222a of the first driving device 22a and the second transmission shaft 222b of the second driving device 22 b; the first transmission main wheel 31 and the second transmission main wheel 41 which are connected to the same first transmission shaft respectively correspond to a first travelling wheel of one travelling device and a second travelling wheel of the other travelling device, the power output by the motor is transmitted to the first travelling wheel through the first transmission shaft, the first transmission main wheel 31, the first transmission belt 33, the first transmission driven wheel 32 and the rotating device 5, and the power output by the motor is transmitted to the second travelling wheel through the first transmission shaft, the second transmission main wheel 41, the second transmission belt 43 and the second transmission driven wheel 42, so that one driving device drives the first travelling wheel of one travelling device and the second travelling wheel of the other travelling device to synchronously rotate;

in addition, by providing the second bearing 53, the second bearing 53 separates the second transmission shaft 51 from the second transmission wheel 42, so that the rotation of the second transmission shaft 51 and the rotation of the second transmission wheel 42 are independently performed, and further the rotation of the first traveling wheel and the rotation of the second traveling wheel of the same traveling device are independently performed.

Optionally, in some embodiments of the present application, as shown in fig. 1 to 9, the first traveling wheels and the second traveling wheels are staggered, so that the first traveling wheels and the second traveling wheels of the same traveling device occupy a smaller installation space, thereby facilitating installation of the traveling device.

Optionally, in some embodiments of the present application, as shown in fig. 1 to 9, the multifunctional robot moving platform further includes a power supply 6 for supplying power to the control mechanism, the first driving device 22a, and the second driving device 22b, the power supply 6 is disposed on the frame 1, the control mechanism and the control component are electrically connected to the power supply 6, and the power supply 6 can ensure normal operation of the control mechanism, the first driving device 22a, and the second driving device 22 b.

Optionally, in some embodiments of the present application, as shown in fig. 1 to 9, the multifunctional robot mobile platform further includes a plurality of obstacle avoidance sensors, the plurality of obstacle avoidance sensors are disposed on the periphery of the frame 1, and each obstacle avoidance sensor is electrically connected to the control mechanism, the obstacle avoidance sensors can sense surrounding road conditions and send road condition information to the control center, when an obstacle appears in the front, the control mechanism controls the first driving device 22a and the second driving device 22b, so that the multifunctional robot mobile platform avoids the obstacle, thereby ensuring normal operation of the robot mobile platform; preferably, the obstacle avoidance sensor is an ultrasonic sensor.

In summary, according to the multifunctional robot mobile platform of the present application, since each traveling wheel of each traveling device is driven by a corresponding driving device, the power of the traveling mechanism 2 is stronger, the application range is wider, and the multifunctional robot mobile platform can pass through complex terrains such as road edges and stairs; in addition, the first driving device 22a is used for driving the first traveling wheel of the first traveling device 21a and the second traveling wheel of the second traveling device 21b to synchronously rotate, and the second driving device 22b is used for driving the second traveling wheel of the first traveling device 21a and the first traveling wheel of the second traveling device 21b to synchronously rotate, compared with the case that each traveling wheel is driven to rotate by a single driving device, the number of driving devices of the traveling mechanism 2 is less, therefore, the design requirement of the robot moving platform on the driving devices is reduced, and the robot moving platform has the advantages of simple structure and controllable cost; in addition, because the walking wheel is wheeled structure again, compare in crawler-type structure, wheeled structure has light in weight, walking speed is fast, the little advantage of jolting, consequently, this multifunctional robot moving platform still has the advantage that the flexibility ratio is higher, the stationarity is better.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, a plurality of modifications and replacements can be made without departing from the technical principle of the present invention, and these modifications and replacements should also be regarded as the protection scope of the present invention.

Claims (10)

1. A multifunctional travelling mechanism is arranged on a frame, the frame is provided with a first direction and a second direction which are perpendicular to each other, and the multifunctional travelling mechanism is characterized by comprising a first travelling device, a second travelling device, a first driving device and a second driving device, wherein the first travelling device and the second travelling device are arranged at intervals along the first direction;

the first driving device is used for driving a first travelling wheel of the first travelling device and a second travelling wheel of the second travelling device to synchronously rotate, and the second driving device is used for driving a second travelling wheel of the first travelling device and a first travelling wheel of the second travelling device to synchronously rotate;

a control mechanism electrically connected to the first drive device and the second drive device.

2. The multi-functional running mechanism of claim 1, wherein the first running wheel and the second running wheel each comprise a hub and a support portion, the hub of the first running wheel is connected to a power output of the first driving device or a power output of the second driving device through a first transmission assembly, and the hub of the second running wheel is connected to a power output of the first driving device or a power output of the second driving device through a second transmission assembly;

the wheel hub has a supporting leg extending in a direction away from the center thereof, and the supporting portion is provided at one end of the supporting leg away from the center of the wheel hub.

3. The multi-function traveling mechanism according to claim 2, wherein the hub has at least two support legs, and all the support legs of the same hub are arranged uniformly in the circumferential direction of the hub.

4. The multi-functional traveling mechanism according to claim 3, wherein any two adjacent support legs of the same first traveling device or the second traveling device have the same angle.

5. The multi-function traveling mechanism according to claim 3, wherein the support legs of the same first traveling device or second traveling device are disposed close to each other in a pair of two by two.

6. The multi-function traveling mechanism according to claim 3, wherein the hub has three support legs, and the three support legs are arranged in a Y-shape.

7. The multi-function traveling mechanism according to claim 3, wherein the supporting portion is a support pad or a roller.

8. The multi-function traveling mechanism according to claim 3, wherein each of the first and second driving units includes an electric motor and a first transmission shaft, the electric motor is provided to the frame, and the first transmission shaft is connected to a motor shaft of the electric motor;

the first transmission assembly comprises a first transmission main wheel, a first transmission driven wheel and a first transmission belt, and the second transmission assembly comprises a second transmission main wheel, a second transmission driven wheel and a second transmission belt;

the first transmission main wheel and the second transmission main wheel are rotationally connected with the first transmission shaft, the first transmission driven wheel is connected with the hub of the first walking wheel through a rotating device, and the first transmission main wheel and the first transmission driven wheel are connected through the first transmission belt;

the second transmission driven wheel is connected with a hub of the second road wheel, and the second transmission main wheel and the second transmission driven wheel are connected through the second transmission belt.

9. The multi-function traveling mechanism according to claim 8, wherein the rotating means includes a second transmission shaft, a first bearing and a second bearing, one end of the second transmission shaft is connected to the frame through the first bearing, the first transmission wheel is in transmission connection with the second transmission shaft, and a hub of the first traveling wheel is rotatably connected to the other end of the second transmission shaft;

the second transmission shaft penetrates through the inner ring of the second bearing, the outer ring of the second bearing is embedded in the inner hole of the second travelling wheel, and the diameter of the inner hole of the second transmission driven wheel is larger than the outer diameter of the second transmission shaft.

10. The multi-function travel mechanism of claim 9, wherein the first travel wheels and the second travel wheels are staggered.

Images